Compound injection molded high pressure laminate flooring

ABSTRACT

The invention relates to a method for fabricating a decorative laminate panel, wherein the decorative laminate panel includes a decorative laminate layer and a core. The method is achieved by forming a decorative laminate of a predetermined size, placing the decorative laminate within a die cavity, injection molding the core within the die cavity while the decorative laminate remains within the die cavity to form a decorative laminate panel and releasing the formed decorative laminate panel from the die cavity. The invention further relates to a decorative laminate panel manufactured in accordance with the method defined above and a unitary edge profile member adapted for use in the fabrication of a compound injection molded decorative laminate panel.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a method for the manufacture of decorativelaminate panels. More particularly, the invention relates to a methodfor compound injection molding decorative laminate flooring planks andplanks manufactured in accordance with the present method.

2. Description of the Prior Art

Decorative laminate panels, and particularly, decorative laminateflooring planks, are commonly manufactured in a linear manner. That is,the various components move through an extensive processing line wherethe various components are bound, cut, sized, shaped, boxed and shipped.

The first step in the linear manufacture of decorative laminate flooringis combining the components of the flooring planks. Specifically, thecores, backing layers and decorative panels are continuously fed andassembled into large decorative panels requiring substantial additionalprocessing before the final product is ready for shipping and use. Oncea large decorative panel is completed and inspected, it is conveyed to aprocessing line where it is machined into a predetermined number offlooring planks. Finally, the finished flooring planks are packaged andpalletized for shipping.

It should be understood that the process described herein is designed tobe continuous. As such, a breakdown occurring at any point in the lineresults in the shutdown of the entire processing line until such a timethat the problem is corrected. The size of the problem is generallyirrelevant and the line must be shut down whether a belt is misalignedor the entire control system goes down.

The use of line processing further limits production capabilities, andnecessitates a substantial investment in updating or replacing equipmentsegments within a processing line once the capacity of a given equipmentsegment reaches its production limit. For example, if a packagingsegment in a flooring plank processing line is capable of packaging 36boxes of 8 planks per hour, the remainder of the line is limited to thiscapacity regardless of whether other equipment segments are capable of agreater output. The replacement or updating of equipment segments toraise the overall line output may continue until such a time that thesize of the processing line exceeds the allotted space. The entireprocessing line must then be moved to a larger space or replaced with anentirely new line. Manufacturers, therefore, attempt to maximize theproduction capabilities of an existing line before investing substantialsums of money into the creation of a new processing line.

However, increased speed is not always an answer to the need forincreased production. When a processing line is pushed to its limits, itis more likely to break down, resulting in down time. In addition, wherea processing line is operating at maximum capacity, for example, 100flooring planks per minute, errors in processing result in the disposalof all items processed during a given time period. When this occurs,1,500 planks would necessarily be thrown away where planks were beingmanufactured in error for a period of only 15 minutes.

In accordance with one known production line, the large decorativepanels are formed as approximately 1.22 m×2.44 m sheets. Each sheet isthen cut into a predetermined number of flooring planks. The edge detailof each plank is then machined and the planks are packaged for shipping.

Extensive and expensive cutting tools are used in converting these largepanels into multiple planks, as well as in machining the required edgeprofile into the flooring planks. The extensive use of cutting toolsadds substantial time and expense to the manufacturing process. Forexample, the positioning and wear status of the cutting tools iscontinuously monitored to ensure the highest quality in the resultingflooring planks. In addition, the cutting tools are preferably diamondtipped and maintenance of these diamond tipped cutting tools addssubstantial expense to the manufacturing process.

In addition to the cost and maintenance problems associated with the useof conventional cutting tools in the manufacture of flooring planks, theuse of cutting tools limits the possible edge profiles that may beformed on the flooring planks. These limitations in turn restrict thepossible designs which might be used to improve the functionality,repairability and installability of flooring planks.

Current machining techniques used in forming desired edge profilesrequire that substantial portions of the core, decorative laminate wearsurface and backer laminate be machined away. This generates substantialand undesirable waste.

As mentioned above, conventional flooring planks are manufactured with adecorative laminate wear surface, a backing layer and a core positionedbetween the wear surface and the backing layer. The use of currentmanufacturing techniques severely limits possible variations which mightimprove the structural characteristics of the flooring planks.

For example, the core or substrate materials commonly used inconventional flooring planks are wood-based and, therefore, susceptibleto the effects of moisture. Moisture renders wood-based substrateshighly susceptible to warping, shrinkage, and separation between thedecorative laminate wear surface, backer layer and the core. Sincecurrent flooring plank manufacturing techniques have been developed toprimarily handle wood-based core materials, their adaptation formanufacturing flooring planks utilizing alternate, waterproof, corematerials is thought to be impractical.

In addition to the water damage to which wood-based flooring planks aresusceptible, the use of wood-based core materials substantially extendsthe time required for producing flooring planks. Before a core materialmay enter the processing line, the core material, for example, mediumdensity fiberboard, must sit in a controlled environment for a period ofapproximately 24 hours to 72 hours to ensure proper temperatureequilibration. Similarly, once the wear surface and backing layer arebonded to the core, and the flooring plank is formed, the finishedflooring plank must further sit and equilibrate for an additional 24hours to 72 hours. This final sitting period allows for the dissipationof stresses from the formed panel.

The extended sitting periods required in the manufacture of decorativelaminate flooring planks necessitate that substantial storage space beprovided. The extended sitting periods further leave the core materialsand finished flooring planks susceptible to damage during the time inwhich they are required to sit. For example, core sheets are oftenpermanently bent or warped during storage and must be thrown away.

Damage to the formed panels and/or planks is also encountered as aresult of the many steps involved in the production thereof. As thoseskilled in the art will certainly appreciate, the components of thepanel are moved many times during production of a flooring plank andeach time the panel, or the components thereof, are moved, there is achance that damage will occur.

The shortcomings of traditional manufacturing processes used in theproduction of decorative laminate flooring planks highlight the need fora new approach in the manufacture of decorative laminate flooringplanks, as well as other decorative laminate products. The presentinvention provides a new and innovative approach to the manufacture ofdecorative laminate flooring planks and other related decorativelaminate products.

SUMMARY OF THE INVENTION

It is, therefore, an object of the present invention to provide a methodfor fabricating a decorative laminate panel, wherein the decorativelaminate panel includes a decorative laminate layer and a core. Themethod is achieved by forming a decorative laminate of a predeterminedsize, placing the decorative laminate within a die cavity, injectionmolding the core within the die cavity while the decorative laminateremains within the die cavity to form a decorative laminate panel andreleasing the formed decorative laminate panel from the die cavity.

It is also an object of the present invention to provide a decorativelaminate panel manufactured in accordance with the method defined above.

It is further an object of the present invention to provide a unitaryedge profile member adapted for use in the fabrication of a compoundinjection molded decorative laminate panel. The unitary member definesan enclosed space and is shaped and dimensioned for receipt of aninjection molded core. The unitary member further includes a radiallyoutwardly facing wall, the outwardly facing wall including a shapedprofile shaped and dimensioned for engagement with the edge profile ofan adjacent decorative laminate panel.

Other objects and advantages of the present invention will becomeapparent from the following detailed description when viewed inconjunction with the accompanying drawings, which set forth certainembodiments of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flow chart of the present method for the compound injectionmolding of decorative laminate planks.

FIG. 2 is a cross sectional view of an open die receiving a wear surfaceand backing layer in accordance with the present invention.

FIG. 3 is a cross sectional view of a closed die in which core materialhas been injected.

FIG. 4 is a cross sectional view of an open die releasing a formedflooring plank in accordance with the present invention.

FIG. 5 is a flow chart of an alternate embodiment of the present methodwhich includes the use of an edge profile member.

FIG. 6 is a cross sectional view of an open die receiving a wearsurface, backing layer and edge profile member in accordance with themethod disclosed in FIG. 5.

FIG. 7 is a top view of the lower die member shown in FIG. 6 with theedge profile member therein.

FIG. 8 is a cross sectional view of a closed die in which core materialhas been injected in accordance with the method disclosed with referenceto FIG. 5.

FIG. 9 is cross sectional view of an open die releasing a formedflooring plank in accordance with the method disclosed in FIG. 5.

FIG. 10 is a cross sectional view of an open die receiving a wearsurface, backing layer and edge profile members in accordance with analternate method.

FIG. 11 is a top view of the lower die member shown in FIG. 10 with theedge profile member thereon.

FIG. 12 is cross sectional view of an open die releasing a formedflooring plank in accordance with the embodiment described withreference to FIG. 10.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The detailed embodiments of the present invention are disclosed herein.It should be understood, however, that the disclosed embodiments aremerely exemplary of the invention, which may be embodied in variousforms. Therefore, the details disclosed herein are not to be interpretedas limited, but merely as the basis for the claims and as a basis forteaching one skilled in the art how to make and/or use the invention.

With reference to FIG. 1, a flow chart of a preferred method inaccordance with the present invention is disclosed. The method generallyrelates to the manufacture of decorative laminate panels, andparticularly, the manufacture of decorative laminate flooring planks.The present method provides for the compound injection molding ofdecorative laminate flooring planks in a piecewise manner. Thiseliminates the problems associated with conventional line techniquesemployed in the prior art and discussed above in the “Background of theInvention”.

The term “flooring planks” is used throughout the body of the presentspecification in describing decorative laminate flooring panels, andshould not be interpreted as limiting the scope of the invention toflooring panels of any specific shape. In fact, the present inventionopens the possibility for the manufacture of flooring plank shapespreviously considered cost prohibitive.

As outlined in FIG. 1 and as shown in FIGS. 2, 3 and 4, a decorativelaminate wear surface 12 is first produced and cut into appropriatesizes for use in conjunction with the compound injection mold die 17employed in accordance with the present process. Cutting is achievedusing conventional sizing techniques adapted to cut laminate sheets todesired sizes and shapes. Such cutting techniques are well known tothose skilled in the art.

In accordance with a preferred embodiment of the present invention, thedecorative laminate wear surface 12 is generally cut in either 39.4 cmby 39.4 cm squares or 118.1 cm by 19.7 cm rectangles, as these arecommonly used shapes in the fabrication and installation of decorativelaminate flooring. As will be better appreciated based upon theforegoing disclosure, the cut sheets of decorative laminate are cutslightly larger than specified above (for example, about 0.381 mm to0.762 mm) to allow for final processing including the removal ofoverhang portions from the decorative laminate wear surface 12 for finalsizing and squaring of the plank.

Similarly, the backing layer 14 is also produced and cut intoappropriate sizes for use in conjunction with the compound injectionmold die 17. As with the decorative laminate wear surface 12, cutting isachieved using conventional laminate sizing techniques which may bereadily adapted to cut laminate sheets to desired sizes and shapes. Thebacking layer 14 is cut to a shape substantially matching, but slightlysmaller than, that of the decorative laminate wear surface 12. However,the backing layer 14 is hidden from the end user's view and it is notcritical that the appearance of the backing layer 14 be maintained atthe same high standards as those applied to the decorative laminate wearsurface 12.

While preferred shapes and dimensions are disclosed above, thedecorative laminate wear surface 12 and backing layer 14 may be cut intoa variety of shapes without departing from the spirit of the presentinvention. In fact, the present invention allows for the production of awide variety of shaped panels (for example, octagons, triangles, etc.).

In addition, it is contemplated that various cutting techniques known tothose skilled in the art may be employed in accordance with the presentinvention. In fact, the cutting of the decorative laminate wear surfaces12 and backing layers 14 need not take place immediately before theinjection molding steps. The decorative laminate wear surfaces 12 andbacking layers 14 may be cut to size and stored under appropriateconditions for later use.

However, it is contemplated that the cutting step and the injectionmolding step will take place as part of a continuous process with thelaminate wear surfaces 12 and backing layers 14 being cut just prior tothe preconditioning and formation of the complete laminate flooringplanks 20. Such a continuous system is believed to be more costeffective since the necessity for storing precut laminate sheets wouldadd additional expense to the process.

Once formed, the cut decorative laminate wear surfaces 12 and backinglayers 14 are preconditioned and conveyed to a die cavity 16 (see FIG.2). The step of preconditioning allows the cut decorative laminate wearsurfaces 12 and backing layers 14 to be physically prepared in order tooptimize the bond created between the core 18, the cut decorativelaminate wear surface 12 and the backing layer 14.

Briefly, and as will be discussed below in greater detail, when the cutdecorative laminate wear surface 12 and backing layer 14 are placedwithin the die cavity 16, the die 17 is closed and core material isinjected within the die cavity 16 to create a panel core 18 (see FIG.3). The core material is chosen to ensure the formation of a secure bondbetween the formed core 18, the decorative laminate wear surface 12 andbacking layer 14 as the molten core material is shot within the diecavity 16.

In accordance with a preferred embodiment of the present invention andconsidering the versatility provided by compound molding techniques, itis contemplated that the core may be formed from a wide variety ofmaterials. For example, the core may be formed from filled plastics,unfilled plastics, ceramics, fibers, polymeric foams, and combinationsthereof. In practice, it is contemplated that the core materials will bechosen to suit specific requirements associated with the intended use ofthe flooring planks. For example, it is contemplated that virgin waterrepellant materials will be used where the planks are likely to beexposed to moisture on a regular basis. However, recycled plastics andplastics including various wood-based products may be used in situationswhere it is unlikely that the flooring planks will be exposed tomoisture.

While contemplated materials are listed above as being exemplary ofthose materials which may be used in accordance with the presentinvention, it should be understood that a wide variety of materials maybe used without departing from the spirit of the present invention.

After the injection of the core material, the cavity 16 remains closedfor a period of time sufficient to allow the flooring plank 20 to set.Finally, the die 17 is opened, the resulting molded flooring plank 20 isreleased from the die cavity 16, and the flooring plank 20 is moved to afixture where the flooring plank 20 is precision machined, for example,CNC machined. The finished plank 20 is then conveyed for packaging andtransport.

Specifically, the flooring plank 20 is machined to remove edges of thedecorative laminate wear surface 12 to ensure that high tolerances aremaintained. By machining the edges of the decorative laminate wearsurface 12 after the injection molding step, one is able to removeirregularities in the edges of the wear surface 12 which may haveoccurred prior to molding and square the plank 20 to a higher tolerancethan previously possible during the initial cutting steps.

While the flooring planks described above are manufactured with abacking layer, it is contemplated that various core materials may permitthe manufacture of flooring planks without the need for the inclusion ofa backing layer. Where such panels are formed in accordance with thepresent invention, the substrate thereof may be formed with structuralribbing designed to add structural stability to the final panel.Structural ribbing may also be included in panels having a backinglayer, although it is believed the inclusion of structural ribbing wouldfind more wide spread applications in instances where the backing layeris not formed with the decorative laminate panel.

By compound injection molding the decorative flooring planks inaccordance with the present invention, many shortcomings of prior artline processing techniques are overcome. For example, limited tooling isrequired for injection molding the decorative laminate flooring planks.In addition, virtually the entire line now used to manufacturedecorative laminate flooring planks could be replaced by a cuttingassembly for the decorative laminate wear surface, a cutting assemblyfor the backing layer, a preliminary conditioning station for the wearsurface and backing layer, a plurality of injection molding dies andfinal processing machinery; providing a substantial savings in bothspace and tooling.

The result of such a process is a reduction in the tooling required forthe processing of decorative laminate flooring planks and a limitednumber of stations which might break down. In fact, if the decorativelaminate wear surface and the backing layer are cut apart from theinjection molding step, only the preconditioning step precedes theinjection molding of the decorative laminate flooring planks. Inaddition, by using multiple injection molding cavities, a shutdown of asingle cavity slows down the fabrication process by one machine and doesnot shut down an entire line as would occur where a machine breaks downin the prior art line processing techniques.

The present compound injection molding process also permits the creationof unique edge profiles, which would be cost prohibitive, or evenimpossible, using conventional cutting techniques employed in the linearprocessing of decorative laminate flooring planks. When compoundinjection molding techniques are employed, the edge profiles which maybe created are only limited by the creativity of those designing theflooring planks. For example, interlocking planks such as thosedisclosed in U.S. Pat. No. 5,618,602, entitled “Articles with Tongue andGroove Joint and Method of Making Such a Joint”, would be easilymanufactured in accordance with the present invention.

Similarly, where prior flooring planks commonly include a flat backingsurface, the use of compound injection molding in the manufacture ofdecorative laminate flooring planks would readily permit the manufactureof flooring planks exhibiting a variety of shapes and textures enhancingthe functionality of the decorative laminate flooring planks.

An alternate embodiment of the present invention is disclosed in FIGS. 5to 9. This embodiment takes advantage of a separate edge profile member115 to enhance the water repellence of the flooring planks 120 andexpand upon the possible edge profiles which may be employed inaccordance with the present invention. The edge profile member 115defines a “window frame” positioned between the decorative laminate wearsurface 112 and the backing layer 114. The edge profile member 115further provides an outer edge on the final decorative laminate flooringplank 120 shaped and dimensioned for permitting ready attachment toadjacent flooring planks 120.

Specifically, and as with the embodiment disclosed in FIGS. 1 to 4, thedecorative laminate wear surface 112 is first produced and then cut intoappropriate sizes for use in conjunction with the compound injectionmold dies 117 employed in accordance with the present process. Thedecorative laminate wear surface 112 is generally cut in either 39.4 cmby 39.4 cm squares or 118.1 cm by 19.7 cm rectangles. As will be betterappreciated based upon the foregoing disclosure, the cut sheets ofdecorative laminate are slightly larger (for example, about 0.381 mm to0.762 mm) to allow for final processing which may remove edge portionsof the decorative laminate wear surface 112.

Similarly, the backing layer 114 is also produced and cut intoappropriate sizes for use in conjunction with the compound injectionmold dies 117 employed in accordance with the present process. As withthe decorative laminate wear surface 112, cutting is achieved usingconventional laminate sizing techniques which may be readily adapted tocut laminate sheets to desired sizes and shapes. The backing layer 114is cut to a shape substantially matching, but slightly smaller than,that of the decorative laminate wear surface 112.

While the backing layer 114 and decorative laminate wear surface 112 arebeing produced and cut into appropriate sizes, the edge profile member115 is also produced. The edge profile member 115 is preferablyinjection molded with a desired edge profile and inner surface. The edgeprofile member may then be machined to remove any undesired markingsremaining after the injection molding thereof.

The edge profile member 115 is preferably injection molded from waterrepellant thermoplastic materials, including, but not limited to,vinyls, polyolefins, styrenics, polyamides, polyimides, polyethers,polyesters, acrylics, acetals, thermoplastic olefins, thermoplasticurethanes and thermoplastic elastomers. In addition, it is alsoenvisioned that the edge member may be formed from thermoset materials,such as, epoxies, polyurethanes, phenolics, melamines, etc. It isfurther contemplated that the edge member may be a foamed thermoplastic.More specifically, the edge profile member 115 is preferably formed fromacrylic-butadiene-styrene (ABS), although other materials may be usedwithout departing from the spirit of the present invention. As thoseskilled in the art of injection molding will understand, the edgeprofile member should be formed from a material having a higher meltingtemperature than that of the core material. This allows for injectionmolding of the core without adversely affecting the previously formededge profile member 115.

As those skilled in the art will certainly appreciate, an almostinfinite variety of edge profiles may be applied to the edge profilemember 115 through the use of injection molding. In addition, injectionmolding of the edge profile member 115 provides highly reproducibleresults ensuring consistent fitting of flooring planks 120 manufacturedin accordance with the present invention.

While the edge profile member is injection molded in accordance with apreferred embodiment of the present invention, it is contemplated thatthe edge profile member may be extruded as multiple pieces (seedisclosure below), or otherwise produced, without departing from thespirit of the present invention.

Referring to FIGS. 6, 7, 8 and 9, once formed the cut decorativelaminate wear surfaces 112, backing layers 114 and edge profile members115 are preconditioned and conveyed to a die cavity 116. The step ofpreconditioning allows the cut decorative laminate wear surfaces 112,backing layers 114 and edge profile members 115 to be physicallyprepared in order to optimize the bond created between the core 118, thecut decorative laminate wear surface 112, the backing layer 114 and edgeprofile member 115.

The cut decorative laminate wear surfaces 112, backing layers 114 andedge profile members 115 are then positioned one at a time forprocessing within the die cavity 116 of the die 117. Briefly, and aswill be discussed below in greater detail, when the cut decorativelaminate wear surface 112, backing layer 114 and edge profile member 115are placed within the die cavity 116, the die 117 is closed and corematerial is injected within the die cavity 116 to create a panel core118. The core material is chosen to ensure the formation of a securebond between the formed core 118 and the decorative laminate wearsurface 112, the backing layer 114 and the edge profile member 115 asthe molten core material is shot within the die cavity 116.

As discussed above, it is contemplated that the core 118 may be formedfrom a wide variety of materials. For example, the core may be formedfrom filled plastics, unfilled plastics, ceramics, fibers, polymericfoams, and combinations thereof. In practice, it is contemplated thatthe core materials will be chosen to suit specific requirementsassociated with the intended use of the flooring planks. However, and incontrast to the embodiment discussed above with reference to FIGS. 1 to4, the core material need not be waterproof as the edge profile member115 will substantially protect the core 118 from water penetrationentering from the sides of the formed flooring planks 120. This permitsthe use of recycled materials which provide desired structural rigiditybut which do not offer desired compositional characteristics (or forwhich the compositional characteristics have not been determined).

While contemplated materials are listed above as being exemplary ofthose materials which may be used in accordance with the presentinvention, it should be understood that a wide variety of materials maybe used without departing from the spirit of the present invention.

As mentioned above, the edge profile member 115 is positioned within thedie cavity 116 to define the edges of the resulting flooring plank 120and to seal the edges of the injected core 118. The edge profile member115 is, therefore, considered to form a “picture frame” about the edgeof the resulting flooring plank 120.

After the injection of the core material, the die 117 remains closed fora period of time sufficient to allow the flooring panel 120 to set.Finally, the die 117 is opened, the resulting molded flooring plank 120is released from the die cavity 116, and the flooring plank 120 is movedto a fixture where the flooring plank is precision machined, forexample, CNC machined. The finished plank 120 is then conveyed forpackaging and transport. Specifically, the flooring plank 120 isprimarily machined to remove overhang of the decorative laminate wearsurface 112 so as to ensure high tolerances are maintained.

As with the embodiment discussed above with regard to FIGS. 1 to 4, theflooring planks 120 described in accordance with the disclosedembodiment are manufactured with a backing layer. However, it iscontemplated that various core materials may permit the manufacture offlooring planks without the need for the inclusion of a backing layer.

As mentioned above with regard to the embodiment disclosed in FIGS. 5 to9, and with reference to FIGS. 10 to 12, the frame defining the edge ofthe flooring plank may be composed of multiple edge profile membersassembled to form a frame. Specifically, these edge profile members 215are produced while the backing layer 214 and decorative laminate wearsurface 212 are being produced and cut into appropriate sizes.

The edge profile members 215 are preferably injection molded with adesired edge profile and subsequently cut (if necessary) to length foruse in the molding step. The edge profile members 215 are preferablyinjection molded from water repellant plastics as listed above. Whilethe edge profile members are injection molded in accordance with apreferred embodiment of the present invention, it is contemplated thatthe edge profile members may be extruded, or otherwise produced, withoutdeparting from the spirit of the present invention.

The cut decorative laminate wear surfaces 212, backing layers 214 andedge profile members 215 are then assembled and molded in the mannerdiscussed above with reference to FIGS. 6, 7, 8 and 9. The onlydifference being that the edge profile members 215 must be individuallypositioned about the circumference of the cavity 216, as opposed to thesingle piece edge profile member 115 employed in accordance with theembodiment previously discussed.

While the preferred embodiments have been shown and described, it willbe understood that there is no intent to limit the invention by suchdisclosure, but rather, is intended to cover all modifications andalternate constructions falling within the spirit and scope of theinvention as defined in the appended claims.

What is claimed is:
 1. A method for fabricating a substantially planar,decorative laminate flooring panel, wherein the decorative laminateflooring panel includes a decorative laminate layer composed of adecorative laminate wear surface, a core, and an edge profile shaped anddimensioned for interlocking engagement with other flooring panels, themethod comprising the following steps: forming a decorative laminatewear surface of a predetermined size; placing the decorative laminatewear surface within a die cavity; the die cavity being shaped anddimensioned for creating an interlocking edge profile along the outerperiphery of the resulting flooring panel; injection molding the corewithin the die cavity while the decorative laminate wear surface remainswithin the die cavity to form a decorative laminate flooring panelincluding a decorative laminate wear surface, a core, and an edgeprofile shaped and dimensioned for interlocking engagement with otherflooring panels; and releasing the formed decorative laminate flooringpanel from the die cavity.
 2. The method according to claim 1, whereinthe core is composed of a material chosen from the group consisting offilled plastics, unfilled plastics, ceramics, fibers, polymeric foams,and combinations thereof.
 3. The method according to claim 1, whereinthe step of forming includes cutting a decorative laminate sheet to apredetermined size to form a cut decorative laminate wear surface. 4.The method according to claim 1, wherein the decorative laminateflooring panel includes a backing layer, and the method includes thefurther step of placing the backing layer within the die cavity.
 5. Themethod according to claim 4, including the step of forming at least oneedge profile member and placing the at least one edge profile memberbetween the decorative laminate wear layer and the backing layer withinthe die cavity for use in the formation of the decorative laminateflooring panel.
 6. The method according to claim 5, wherein the edgeprofile member is formed from a material chosen from the groupconsisting of vinyls, polyolefins, styrenics, polyamides, polyimides,polyethers, polyesters, acrylics, acetals, thermoplastic olefins,thermoplastic urethanes, thermoplastic elastomers, epoxies,polyurethanes, phenolics and melamines.
 7. The method according to claim6, wherein the edge profile member is formed fromacrylic-butadiene-styrene.
 8. The method according to claim 5, whereinthe step of forming the edge profile member includes injection moldingthe edge profile member.
 9. The method according to claim 4, wherein thebacking layer is formed by the additional step of cutting a decorativebacking layer to a predetermined size to form a cut backing layer. 10.The method according to claim 1, wherein the decorative laminateflooring panel includes a backing layer, and the method includes thefurther step of placing the backing layer within the die cavity.
 11. Themethod according to claim 10, wherein the edge profile member is formedfrom a material chosen from the group consisting of vinyls, polyolefins,styrenics, polyamides, polyimides, polyethers, polyesters, acrylics,acetals, thermoplastic olefins, thermoplastic urethanes, thermoplasticelastomers, epoxies, polyethanes, phenolics and melamines.
 12. Themethod according to claim 11, wherein the edge profile member is formedfrom acrylic-butadiene-styrene.
 13. The method according to claim 10,wherein the step of forming the edge profile member includes injectionmolding the edge profile member.
 14. The method according to claim 10,wherein the step of placing includes positioning the edge profile memberbeneath the decorative laminate wear layer such that it defines an outeredge of the formed decorative laminate flooring panel.